FR3080253A1 - RESOURCE ALLOCATION METHOD, RESOURCE ALLOCATION RECEIVING METHOD, COMPUTER PROGRAM PRODUCTS, CORRESPONDING MODULES AND SIGNAL - Google Patents

Abstract

The invention relates to a method for allocating resources on an uplink between a terminal and a base station of a radiocommunication network that multiplexes the data in resource blocks. The method implements: a first standard allocation mode, associated with a standard transmission mode by the terminal; and a second priority allocation mode, associated with a priority transmission mode by the terminal. The network favors the priority allocation mode and can allocate to the terminal, according to the priority allocation mode, a previously allocated resource block according to the standard allocation mode, introducing a collision situation. In such a situation, the network implements a temporary allocation mode for allocating an alternative resource block in the standard transmission mode, implementing a number of signaling portions containing allocation information greater than that used. in the standard allocation mode.

Description

Resource allocation method, resource allocation reception method, computer program products, modules and corresponding signal.

TECHNICAL AREA

The field of the invention is that of the implementation of radiocommunication networks. The invention relates more particularly to the reduction of latency in such radiocommunication networks.

The invention has numerous applications, in particular, but not exclusively, in the field of cellular radiocommunication networks conforming to 3GPP standards (for “3rd Generation Partnership Project” in English) of last generations and / or future, in particular for terminals. can implement several categories, or modes, of transmission.

TECHNOLOGICAL BACKGROUND

New generation cellular networks, in particular the 5G networks undergoing standardization within 3GPP, are planned from their design to support different categories of services, each category having different technological constraints.

For example, 5G networks are developed around three categories of services corresponding to three modes of transmission implemented to exchange data between the base station and the terminals connected to it. More particularly, the three modes in question are:

mMTC (for “massive Machine Type Communications” in English), more particularly intended for low speed and low consumption transmissions of the “connected object” type;

eMBB ("enhanced Mobile Broadband" in English), more particularly intended for very high speed data transmissions; and

URLLC (“UItra-Reliable and Low Latency Communications” in English), more particularly intended for data transmissions with very low latency in the network.

Among the characteristics specific to each mode of transmission is the method of access by the terminals to the radio resources available on the uplink in the direction of the base station, and therefore of allocation of these resources.

For example, since mMTC transmissions are adapted to “connected objects”, access to resources on the uplink is conventionally done by contention. In other words, the terminals decide for themselves to access the media and to start a transmission using a particular radio resource among those dedicated to this type of transmission. This makes it possible to avoid requesting and resource allocation mechanisms which are costly in terms of signaling, but at the cost of potential collisions in the network.

Conversely, eMBB and URLLC type transmissions are intended for higher bit rates. To keep the additional cost of signaling low compared to the data rate, access to radio resources by the terminals is conventionally done by scheduling: the terminals obey a base station which specifically allocates the available resources. In practice, the terminal sends an allocation request (“Scheduling Request”, or SR, in English) to the network, in particular to the base station, to which the network responds with an allocation of a particular resource on the uplink. (“Uplink grant”, or UL, in English). The terminal then transmits its data to the base station via the radio resource previously allocated according to this mechanism.

However, eMBB and URLLC type transmissions do not have the same priority. Since URLLC transmissions are generally associated with services which require very low latency in the network, for example for remote medicine or autonomous vehicle applications, radio resources on the uplink are allocated to them as a priority. In this way, for a terminal implementing both transmissions of the eMBB type and transmissions of the URLLC type, it may happen that one or more transmissions of the eMBB type are shifted to a later instant due to a situation of time collision with a transmission of the URLLC type which is allocated resources on the uplink as a priority.

The risk is that, in certain cases, the discrepancy is repeated several times, and that the allocation to a service implementing an eMBB type transmission, or more generally less demanding in terms of reactivity, is ultimately strongly, or even too much, deferred. There is thus a need to control the latency in such networks, in particular for transmissions of lower priority, for example transmissions of the eMBB type.

ABSTRACT

Thus, according to a first aspect, the invention relates to a method for allocating resources on an uplink between a user terminal and a base station of a radiocommunication network multiplexing the data in resource blocks distributed in time and in frequency in time intervals. Such an allocation method implements at least two modes of resource allocation:

a first allocation mode, called standard allocation mode, associated with a first mode of transmission by the terminal, called standard transmission mode, and implementing at least one signaling portion containing resource allocation information in each time interval; and a second allocation mode, called priority allocation mode, associated with a second mode of transmission by the terminal, called priority transmission mode.

According to the invention, the network favors the priority allocation mode and can allocate to the terminal, according to the priority allocation mode, at least one resource block previously allocated according to the standard allocation mode, introducing a collision situation d 'allocation. In such a collision situation, the network implements a temporary allocation mode to allocate at least one replacement resource block in the standard transmission mode, implementing a number of signaling portions containing allocation information. of resource greater than that used in the standard allocation mode, in each time interval.

Thus, the invention proposes a new and inventive solution to allow the reduction of the latency associated with the standard transmission mode in the radiocommunication network, consisting in temporarily adopting an allocation mode having a higher signaling frequency for this mode standard transmission.

More particularly, by switching to the temporary allocation mode having a signaling frequency higher than the standard mode, the terminal is more likely to be allocated within a short period of new resources on the uplink in order to transmit the data in waiting following the time collision. This reduces the latency associated with the standard transmission mode in the radio network.

According to a particular embodiment, the allocation method comprises the following steps:

allocation, at the terminal, of at least a first resource block on the uplink according to the standard allocation mode;

allocation, at the terminal, of at least the first resource block on the uplink according to the priority allocation mode;

detecting a time collision situation between the allocations of said at least one first resource block; and temporary change of the resource allocation mode associated with the standard transmission mode from the standard allocation mode to the temporary allocation mode to allocate said at least one replacement resource block, the temporary change being triggered by the detection .

According to a particular embodiment, the allocation method further comprises a step of returning to the standard allocation mode for the standard transmission mode, following the allocation of said at least one replacement resource block.

Thus, the overconsumption linked to the use of the temporary allocation mode is controlled (the temporary allocation mode being more energy consuming than the standard mode due to the higher frequency of signaling).

The invention also relates to a method of reception, by a user terminal, of resource allocation on an uplink between the terminal and a base station of a radiocommunication network multiplexing the data in resource blocks distributed in time and in frequency in time intervals.

Such a reception method receives resource allocation information according to at least two resource allocation modes:

a first mode of allocation of resources by the network, called standard allocation mode, associated with a first mode of transmission by the terminal, called standard transmission mode, the standard allocation mode implementing at least a portion of signaling containing resource allocation information in each time interval; and a second mode of allocation of resources by the network, said priority allocation mode, associated with a second mode of transmission by the terminal, said priority mode of transmission.

According to the invention, when at least one resource block previously allocated according to the standard allocation mode is then allocated according to the priority allocation mode, introducing an allocation collision situation, the terminal receives allocation information of resources according to a temporary allocation mode for the allocation of at least one replacement resource block in the standard transmission mode, implementing a number of signaling portions of signaling portions greater than that used in the mode standard allocation, in each time interval.

Thus, the terminal implements the principle of the invention by implementing symmetrical steps to those implemented by the network without requiring additional signaling. This further minimizes the overall consumption of the system as well as the network load.

According to a particular embodiment, the allocation reception method comprises the following steps:

reception of an allocation of at least a first resource block on the uplink allocated according to the standard allocation mode;

receiving an allocation of said at least first resource block on the uplink allocated according to the priority allocation mode;

detecting a time collision situation between the allocations of said at least one first resource block; and temporarily changing the resource allocation reception mode associated with the standard transmission mode from the standard allocation reception mode to the temporary allocation reception mode to receive the allocation of said at least one replacement resource block , the temporary change being triggered by detection.

According to a particular embodiment, the allocation reception method further comprises a step of returning to the standard allocation reception mode for the standard transmission mode following reception of the allocation of said at least one resource block. of substitution.

Thus, the overconsumption linked to the use of the priority reception mode is controlled.

According to a particular embodiment, for at least one given resource block allocated selectively according to the standard allocation mode or the temporary allocation mode for the standard transmission mode, allocation information of said at least one resource block given are transmitted to the terminal in at least one resource block of a signaling portion, called a common resource block.

Thus, the terminal is able to receive a resource allocation even though the allocation reception mode that it implements is not the reception mode adapted to the allocation mode implemented by the network.

In this case, according to an efficient approach, said at least one common resource block comprises an allocation mode identification field indicating to the terminal which of the standard and temporary allocation modes is implemented in the transmission mode. standard.

Thus, the terminal is able to determine whether the allocation reception mode that it implements is actually that adapted to the allocation mode implemented on the network side, or if it has to change its reception mode. .

According to a particular embodiment, following a collision situation, the temporary allocation mode is implemented for a predetermined period of time, for the allocation of at least one replacement resource block for the transmission mode. standard. After said period of time, the standard allocation mode is again implemented.

In this case, according to an effective approach, the allocation method or the allocation reception method further comprises the following steps:

triggering, upon detection of the time collision situation, of a counter; and return to the standard allocation mode for the standard transmission mode, if the allocation mode commonly associated with the standard transmission mode is the temporary allocation mode, and the counter indicates that a predetermined period of time has elapsed. has elapsed since the trip.

Thus, if when the predetermined period of time has elapsed the network has not yet been able to allocate resources to the terminal according to the temporary allocation mode (for example if the network is busy because it is too busy), the allocation and reception all the same return to standard modes in order to control the energy consumption of the system.

According to a particular embodiment, the standard allocation mode uses to signal allocations to the terminal only resource blocks joined temporally at the start or at the end of time intervals on a downlink between the base station and the terminal . The temporary allocation mode is used to signal allocations to the terminal of resource blocks distributed according to a time diagram equally distributed within time intervals on the downlink (for example the time intervals are the radio frames according to the standard set radio network).

According to a particular embodiment, the radiocommunication network is of the fifth generation cellular type, the standard transmission mode is of the eMMB type (for “enhanced Mobile Broadband” in English), and the priority transmission mode is of the URLLC type ( for "UItra-Reliable and Low Latency Communications" in English).

The invention also relates to a computer program product comprising program code instructions for executing the steps of the allocation method or of the allocation reception method as described above.

The invention also relates to a resource allocation module. Such an allocation module is in particular capable of implementing the resource allocation method according to the invention (according to any one of the different embodiments mentioned above). Thus, the characteristics and advantages of this module are the same as those of the allocation method described above. Therefore, they are not further detailed.

The invention also relates to a resource allocation reception module. Such an allocation reception module is in particular capable of implementing the resource allocation reception method according to the invention (according to any one of the various embodiments mentioned above). Thus, the characteristics and advantages of this module are the same as those of the allocation reception method described above. Therefore, they are not further detailed.

It is noted here that, depending on the implementations and developments, such modules may include hardware (“hardware” in English) and / or software (“software” in English) means. A module can also consist of several elements, or modules, distinct, hardware and / or software interacting with each other.

The invention also relates to a signal transmitted by a base station of a radiocommunication network to at least one terminal, multiplexing data in resource blocks distributed in time and frequency in time intervals. Such a signal comprises at least one signaling portion for the allocation of resources comprising an identification field of the allocation mode implemented in the signaling portion, among standard and temporary allocation modes.

LIST OF FIGURES

Other characteristics and advantages of the invention will appear on reading the following description, given by way of an indicative and nonlimiting example, and the appended drawings, in which:

FIGS. 1, 2a and 2b illustrate the problem of temporal collision between resources allocated, according to the prior art, on the uplink between a terminal and a base station according to two allocation modes associated respectively with two transmission modes of the terminal of different priorities;

FIG. 3 illustrates steps of a method for allocating resources on the uplink between the terminal and the base station of FIG. 1 according to an embodiment of the invention;

FIG. 4 illustrates steps of a method of reception, by the terminal of FIG. 1, of allocation of resources on the uplink in question according to an embodiment of the invention;

FIGS. 5a and 5b illustrate the temporary change, obtained by applying the methods of FIGS. 3 and 4, of the allocation mode associated with the lower priority transmission mode of the terminal in FIG. 1;

FIG. 6 illustrates a variant of signaling used in the allocation modes associated with the lower priority transmission mode of the terminal;

FIG. 7 presents a simplified example of the structure of a module intended to implement the allocation method of FIG. 3; and FIG. 8 presents a simplified example of the structure of a module intended to implement the allocation reception method of FIG. 4.

DETAILED DESCRIPTION OF THE INVENTION

In all the figures in this document, identical elements and steps are designated by the same reference.

5.1 problem to which the invention responds

We will now describe, in relation to FIGS. 1, 2a and 2b, the problem with which the inventor was confronted in the context of a terminal 100 supporting two modes of transmission on the uplink, or UL (for “Up Link”). in English), to the base station 110 of a 5G network when the two modes in question have different priority levels. The invention is of course not limited to this particular type of fifth generation radiocommunication network, but is of interest for any type of network serving terminals supporting at least two types of transmission with different priority levels.

Thus, the terminal 100 supports:

a first transmission mode having a given priority level, called standard transmission mode, for example a transmission of the eMBB type. In the eMBB case, it is an allocation implementing a single allocation zone per time interval (“slot based” or “SB” allocation); and a second transmission mode having a priority level higher than the standard level, called priority transmission mode. This is for example a transmission of the URLLC type requiring reduced latency in the network compared to the standard transmission of the eMBB type. In this case URLLC, it is an allocation implementing several allocation zones per time interval (“non slot based” or “NSB” allocation).

As discussed above, for such transmission modes, access to radio resources on the uplink is done by scheduling. The network in question multiplexes the data in resource blocks distributed in time and in frequency in time intervals 210 (for example the radio frames of the standard considered). In this way, to allocate resource blocks on the uplink to the terminal 100, the base station 110 (or alternatively a remote planner 120 for example), implements:

the standard allocation mode associated with the standard transmission mode; and the priority allocation mode associated with the priority transmission mode.

In variants, the allocation modes in question are implemented by a remote planner 120 in the network. In other variants not illustrated, the allocation modes are implemented in other remote devices in a network server.

Returning to FIGS. 1, 2a and 2b, the standard allocation mode uses for example to signal allocations to the terminal 100 only resource blocks 200s of signaling portions (for example "occasion monitoring" in the sense of 3GPP) joined temporally at the start or end of time intervals 210 on a downlink, or DL (for “Down Link” in English), between the base station 110 and the terminal 100 (for example the first three blocks of resource of each radio frame). Such a signaling implementing a reduced number of signaling portions per time interval 210 makes it possible for example to reduce the consumption of the terminal 100 by allowing it to listen to the signaling channels of the network only a reduced number of times per interval of time 210.

Conversely, the priority transmission mode requiring reduced latency in the network compared to standard transmission, the priority allocation mode uses for its signaling resource blocks 200p of signaling portions distributed throughout the time intervals 210 in order to reduce the delays linked to the exchange of information between the terminal 100 and the base station 110 even though this induces overconsumption at the level of the terminal 100.

In such a context, as the network favors the priority allocation mode, it may happen that it allocates to the terminal 100, according to the priority allocation mode, at least one resource block 250 on the uplink which had been previously allocated according to the standard allocation mode, introducing an allocation collision situation as illustrated in FIG. 2a.

In such a situation, the terminal 100 cannot use the same resource block 250 on the uplink for the simultaneous transmission according to the two transmission modes and therefore also favors the priority transmission mode. The terminal 100 thus transmits to the base station 110 the data associated with the priority transmission mode using the resource block 250.

The terminal then waits to receive a new allocation via a new resource block 200s 'from another signaling portion in order to be allocated a new resource block 250' on the uplink according to the standard allocation mode as illustrated in Figure 2b.

Such a mechanism thus induces increased latency for the standard transmission mode, in particular if it is repeated.

5.2 optimization of the allocation according to the invention

Now described in relation to FIGS. 3 and 4, the steps of a method for allocating resources on the uplink between the terminal 100 and the base station 110, as well as the steps of a reception method, by the terminal 100, for allocating resources on the uplink in question according to different embodiments of the invention. Furthermore, the steps in question as well as their implementation in different embodiments considered are illustrated by examples described in relation to FIGS. 5a, 5b and 6.

More particularly, according to the proposed approach, in a collision situation as described above in relation to FIGS. 2a and 2b, the network implements a temporary allocation mode to allocate at least one replacement resource block 250r in the standard transmission mode to allow the terminal to transmit the data associated with the standard transmission mode that it could not transmit in the resource block 250. Conversely, the terminal 100 receives the resource allocation information according to the temporary allocation mode for the allocation of at least the replacement resource block 250r in the standard transmission mode.

Furthermore, the temporary allocation mode uses to report allocations to the terminal 100 of resource blocks 200r of signaling portions which are present in a number greater than that used in the standard allocation mode, in each time interval. For example, in a variant, the temporary allocation mode uses resource blocks 200r of signaling portions distributed according to an evenly distributed time scheme within time intervals 210 on the downlink whereas the standard allocation mode uses only resource blocks 200s of signaling portions joined temporally at the start or at the end of time intervals 210. In another variant, the temporary allocation mode uses resource blocks 200r of signaling portions distributed according to a diagram identical in time to that implemented by the priority allocation method. In this way, the number of time diagrams to be managed by the terminal 100 is minimized.

Whatever the signaling variant considered for the temporary allocation mode, the terminal 100 is thus more likely to be allocated within a short time the replacement resource block 250r in order to transmit the data associated with the transmission mode. standard which are on standby following the time collision situation. This reduces the latency associated with the standard transmission mode in the radio network.

Thus, according to the invention, at least one of the transmission modes, in particular the standard transmission mode, is associated with two distinct allocation modes, selectively implemented. In particular, one can go from a standard allocation mode of type SB to a temporary allocation mode of type NSB.

5.3 allocation process

To obtain this result, the network can implement the following steps (Figure 3):

allocation E300, at terminal 100, of at least one resource block 250 on the uplink according to the standard allocation mode;

allocation E310, at terminal 100, of at least the same resource block 250 on the uplink according to the priority allocation mode;

detection E320 of a time collision situation between the allocations of the resource block 250; and temporary change E430 (illustrated by the arrow 500 in FIGS. 5a and 5b) from the resource allocation mode associated with the standard transmission mode from the standard allocation mode to the temporary allocation mode to allocate E340 the block of replacement resource 250r. The temporary change is also triggered by the detection of the collision situation.

5.4 allocation reception process implemented in the terminal

Symmetrically, the terminal implements the following steps (figure

4):

reception E400 of an allocation of at least one resource block 250 on the uplink allocated according to the standard allocation mode;

reception E410 of an allocation of at least the same resource block 250 on the uplink allocated according to the priority allocation mode;

detection E420 of a time collision situation between the allocations of the at least one resource block 250; and temporary change E430 of the resource allocation reception mode associated with the standard transmission mode from the standard allocation reception mode to the temporary allocation reception mode to receive E440 the allocation of the replacement resource block 250r . The temporary change is also triggered by the detection of the collision situation.

In variants, the temporary change E430 is triggered in the terminal 100 by the effective transmission of the data associated with the priority transmission mode via the resource block 250.

Returning to FIG. 4, it is noted that the terminal implements the invention by implementing the symmetrical steps of those implemented by the network without requiring additional signaling between the base station 110 and the terminal 100. This further minimizes the overall consumption of the system, and in particular that of the terminal 100, as well as the network load.

To do this, the standard and temporary allocation reception modes are for example programmed by the network on the terminal 100 when the latter connects to the base station 110 (for example via the RRC protocol layer for “Radio Resource Control” ).

Conversely, in other embodiments not illustrated, the terminal 100 is a slave to the network and receives information for temporary change in allocation allocation mode from the base station 110. Thus, the terminal 100 does not have to implement by itself the change in the allocation reception mode associated with the standard transmission. Furthermore, the network remains master of the allocation reception mode implemented by the terminal 100, thereby avoiding any misalignment between the allocation mode implemented by the network and the allocation reception mode set implemented by terminal 100.

5.5 interruption of the temporary allocation method

In the embodiment illustrated in FIG. 3, the end of the implementation of the temporary allocation mode is triggered by the allocation to the terminal 100 of the replacement resource block 250r.

In this way, the network implements in this embodiment a step E350 of returning to the standard allocation mode (materialized by the arrow 550 in FIG. 5b) for the standard transmission mode, following the allocation of the block. replacement resource 250r.

Thus, the overconsumption linked to the use of the priority temporary allocation mode is controlled (the priority temporary allocation mode being more energy-consuming than the standard mode due to the higher frequency of signaling).

Symmetrically, the terminal implements (FIG. 4) a step E450 of returning to the standard allocation reception mode for the standard transmission mode following the reception of the allocation from the replacement resource block 250r.

In variants, other criteria can also be taken into account to trigger the return to the implementation of the standard allocation mode for the standard transmission mode. For example, a criterion for the end of the collision situation as described above can also be taken into account (alone or in combination with the aforementioned criterion for allocating the replacement resource block 250r). Indeed, such a collision situation can persist over time in the event of significant radio resource requirements for the priority transmission mode.

In the embodiment illustrated in FIGS. 3 and 4, the temporary allocation mode is implemented for a predetermined period of time, for the allocation of the replacement resource block 250r. In this way, after the lapse of time, the standard allocation mode is again implemented systematically.

To do this, the network (FIG. 3), respectively the terminal (FIG. 4), implement a triggering step E360, respectively E460, with detection of the situation of temporal collision, of a counter. In this case, the return step E350, respectively E450, to the standard allocation mode for the standard transmission mode is implemented if the allocation mode commonly associated with the standard transmission mode is the temporary allocation mode , and that the counter indicates that a predetermined period of time has elapsed since the trigger in question.

Thus, when the predetermined period of time has elapsed, if the network has not yet been able to allocate resources to the terminal according to the temporary allocation mode (for example if the network is busy because it is too busy), the allocation modes and However, the corresponding reception systems return to the standard modes in order to control the energy consumption of the system.

However, in other embodiments not illustrated, such a mechanism for returning to the standard allocation mode after a predetermined period of time is not implemented in order to maximize the chances of being allocated a resource block of replacement via the temporary allocation mode even when the network is loaded.

5.6 use of resource blocks common to both allocation methods

In a variant of signaling illustrated in FIG. 6, the standard and temporary allocation modes use, for signaling allocations to the terminal, certain resource blocks 600c in common.

Indeed, as illustrated in FIG. 5b, the base station 110 returns to the implementation of the standard allocation mode when it has allocated the replacement block 250r according to the temporary allocation mode (step E350 mentioned above). Symmetrically, the terminal again implements the standard allocation reception mode for the standard transmission mode following reception of the allocation of the replacement resource block 250r (step E450 mentioned above). However, it may happen that the terminal 100 does not receive the allocation according to the temporary allocation mode (for example if the propagation conditions are so bad that the terminal could not decode the received signal).

In this case, the allocation reception mode implemented by the terminal 100 remains the temporary mode while the allocation mode implemented by the network becomes again the standard mode, thereby leading to a misalignment between the terminal 100 and the network. Thus, the use of resource blocks 600c in common allows the terminal to receive a resource allocation even though the allocation reception mode which it implements is not the reception mode adapted to the mode of allocation implemented by the network.

5.7 signaling for common resource blocks

In some variants, the common resource blocks 600c include an allocation mode identification field indicating to the terminal 100 which of the standard and temporary allocation modes is implemented by the network in the standard transmission mode. This is for example an information bit indicating the allocation mode used.

Thus, the terminal is able to determine if the allocation reception mode that it implements is actually that adapted to the allocation mode implemented on the network side, or if it has to change its reception mode .

5.8 examples of process implementation

FIG. 7 shows an example of a resource allocation module 700. More particularly, such a module 700 allows the implementation of the resource allocation method of FIG. 3. The module 700 comprises a random access memory 703 (for example a RAM memory), a processing unit 702 equipped for example with a processor, and controlled by a computer program stored in a read-only memory 701 (for example a ROM memory or a hard disk). On initialization, the code instructions of the computer program are for example loaded into the random access memory 703 before being executed by the processor of the processing unit 702.

This FIG. 7 illustrates only one particular way, among several possible, of realizing the means included in the module 700, so that it performs certain steps of the resource allocation method detailed above, in relation to FIG. 3 (in any of the different embodiments). Indeed, these steps can be carried out indifferently on a reprogrammable calculation machine (a PC computer, a DSP processor or a microcontroller) executing a program comprising a sequence of instructions, or on a dedicated calculation machine (for example a set of logic gates like an FPGA or an ASIC, or any other hardware module). In the case where the means included in the module 700 are produced with a reprogrammable calculation machine, the corresponding program (that is to say the sequence of instructions) may be stored in a removable storage medium (such as by example a floppy disk, a CD-ROM or a DVD-ROM) or not, this storage medium being partially or totally readable by a computer or a processor.

In some embodiments, such a module 700 is included in the terminal 100. In other embodiments, the resource allocation module 700 according to the invention is software embedded, for example in the overall software of the terminal 100 .

FIG. 8 shows an example of module 800 for receiving resource allocation. More particularly, such a module 800 allows the implementation of the resource allocation reception method of FIG. 4. The module 800 comprises a random access memory 803 (for example a RAM memory), a processing unit 802 equipped for example of a processor, and controlled by a computer program stored in a read-only memory 801 (for example a ROM memory or a hard disk). On initialization, the code instructions of the computer program are for example loaded into the random access memory 803 before being executed by the processor of the processing unit 802.

This FIG. 8 illustrates only one particular way, among several possible, of realizing the means included in the module 800, so that it performs certain steps of the resource allocation reception method detailed above, in relation to FIG. 4 (in any of the different embodiments). Indeed, these steps can be carried out indifferently on a reprogrammable calculation machine (a PC computer, a DSP processor or a microcontroller) executing a program comprising a sequence of instructions, or on a dedicated calculation machine (for example a set of logic gates like an FPGA or an ASIC, or any other hardware module). In the case where the means included in the module 800 are produced with a reprogrammable calculation machine, the corresponding program (that is to say the sequence of instructions) may be stored in a removable storage medium (such as by example a floppy disk, a CD-ROM or a DVD-ROM) or not, this storage medium being partially or totally readable by a computer or a processor.

In certain embodiments, such a module 800 is included for example in the base station 110 or in a remote planner 120 in the network. In other embodiments, the module 800 for receiving resource allocation according to the invention is software embedded, for example in the overall software of the base station 110 or of the planner 120.

Claims (15)

1. Method for allocating resources on an uplink (UL) between a user terminal (100) and a base station (110) of a radiocommunication network multiplexing the data in distributed resource blocks (250, 250r) in time and frequency in time intervals (210), said allocation method implementing at least two modes of resource allocation: a first allocation mode, called standard allocation mode, associated with a first mode of transmission by said terminal, called standard transmission mode, and implementing at least one signaling portion containing resource allocation information in each time interval; and a second allocation mode, said priority allocation mode, associated with a second mode of transmission by said terminal, said priority transmission mode, characterized in that said network promotes said priority allocation mode and can allocate to said terminal , according to said priority allocation mode, at least one resource block (250) previously allocated according to said standard allocation mode, introducing an allocation collision situation, and in that, in such a collision situation, said network implements a temporary allocation mode to allocate at least one replacement resource block (250r) in the standard transmission mode, implementing a higher number of signaling portions containing resource allocation information than that used in the standard allocation mode, in each time interval. 2. Allocation method according to claim 1 comprising the following steps: allocation (E300), to said terminal, of at least a first resource block on the uplink according to the standard allocation mode; allocation (E310), to said terminal, of at least said first resource block on the uplink according to the priority allocation mode; detection (E320) of a time collision situation between said allocations of said at least one first resource block; and temporary change (E330) of the resource allocation mode associated with said standard transmission mode from said standard allocation mode to the temporary allocation mode to allocate (E340) said at least one replacement resource block, said change being triggered by said detection. 3. The allocation method according to claim 2 further comprising a step of returning (E350) to the standard allocation mode for the standard transmission mode, following the allocation of said at least one replacement resource block. 4. Method for reception, by a user terminal (100), of resource allocation on an uplink (UL) between said terminal and a base station (110) of a radiocommunication network multiplexing the data in blocks of resource (250, 250r) distributed in time and frequency in time intervals (210), said reception method receiving resource allocation information according to at least two modes of resource allocation: a first mode of allocation of resources by the network, called standard allocation mode, associated with a first mode of transmission by said terminal, said standard transmission mode, said standard allocation mode implementing at least a portion of signaling containing resource allocation information in each time interval; and a second mode of allocation of resources by the network, said priority allocation mode, associated with a second mode of transmission by said terminal, said priority mode of transmission, characterized in that, when at least one resource block (250) previously allocated according to said standard allocation mode is then allocated according to said priority allocation mode, introducing an allocation collision situation, said terminal receives resource allocation information according to a temporary allocation mode for the allocation of at least one replacement resource block (250r) in the standard transmission mode, implementing a number of signaling portions of signaling portions greater than that used in the standard allocation mode, in each time interval. 5. An allocation reception method according to claim 4 comprising the following steps: receiving (E400) an allocation of at least a first resource block on the uplink allocated according to said standard allocation mode; receiving (E410) an allocation of said at least first resource block on the uplink allocated according to the priority allocation mode; detecting (E420) a time collision situation between said allocations of said at least one first resource block; and temporarily changing (E430) the resource allocation reception mode associated with said standard transmission mode from said standard allocation reception mode to the temporary allocation reception mode for receiving (E440) said allocation of said at least one replacement resource block, said temporary change being triggered by said detection. 6. Allocation reception method according to claim 5 comprising in a step of returning (E450) to the standard allocation reception mode for the standard transmission mode following the reception of said allocation of said at least one resource block of replacement. 7. Allocation method according to any one of claims 1 to 3 or receiving allocation according to any one of claims 4 to 6, characterized in that, for at least one given resource block allocated selectively according to the standard allocation mode or the temporary allocation mode for said standard transmission mode, allocation information of said at least one given resource block is transmitted to the terminal in at least one resource block of a signaling portion , says common resource block. 8. Method according to claim 7, characterized in that said at least one common resource block comprises an allocation mode identification field indicating to said terminal which of the standard and temporary allocation modes is implemented in the standard transmission mode. 9. Method according to any one of claims 1 to 8, characterized in that, following a collision situation, said temporary allocation mode is implemented for a predetermined period of time, for the allocation of at least minus a replacement resource block for the standard transmission mode, and in that after said period of time, said standard allocation mode is again implemented. 10. Method according to any one of claims 1 to 9, in which said standard allocation mode uses to signal allocations to said terminal only resource blocks joined temporally at the start or at the end of time intervals on a channel. downlink between said base station and said terminal, and wherein said temporary allocation mode uses to report allocations to said terminal of resource blocks distributed according to a time diagram distributed equally within time slots on the downlink. 11. Method according to any one of claims 1 to 10, in which said radiocommunication network is of the fifth generation cellular type, in which said standard mode of transmission is of eMMB type (for “enhanced Mobile Broadband” in English), and in which said priority transmission mode is of the URLLC type (for “Ultra24 Reliable and Low Latency Communications ”. 12. A computer program product comprising program code instructions for implementing a method according to any one of claims 1 to 11, when said program is executed on a computer. 13. Resource allocation module (700) on an uplink (UL) between a user terminal (100) and a base station (120) of a radiocommunication network multiplexing the data in resource blocks (250, 250r) distributed in time and frequency in time intervals, said allocation module comprising allocation means (702) implementing at least two modes of resource allocation: a first allocation mode, called standard allocation mode, associated with a first mode of transmission by said terminal, called standard transmission mode, and implementing at least one signaling portion containing resource allocation information in each time interval; and a second allocation mode, said priority allocation mode, associated with a second mode of transmission by said terminal, said priority transmission mode, characterized in that said means favor said priority allocation mode and can allocate to said terminal , according to said priority allocation mode, at least one resource block (250) previously allocated according to said standard allocation mode, introducing an allocation collision situation, and in that, in such a collision situation, said means implement a temporary allocation mode to allocate at least one replacement resource block (250r) in the standard transmission mode, implementing a number of signaling portions containing resource allocation information greater than that used in the standard allocation mode, in each time interval. 14. Reception module (800), by a user terminal (100), for allocating resources on an uplink (UL) between said terminal and a base station (120) of a radiocommunication network multiplexing the data in blocks resources distributed in time and frequency in time intervals, said reception module comprising means for receiving (802) resource allocation information according to at least two resource allocation modes: a first mode of allocation of resources by the network, called standard allocation mode, associated with a first mode of transmission by said terminal, said standard transmission mode, said standard allocation mode implementing at least a portion of signaling containing resource allocation information in each time interval; and a second mode of allocation of resources by the network, said priority allocation mode, associated with a second mode of transmission by said terminal, said priority mode of transmission, characterized in that, when at least one resource block (250) previously allocated according to said standard allocation mode is then allocated according to said priority allocation mode, introducing an allocation collision situation, said means receive resource allocation information according to a temporary allocation mode for the allocation of at least one replacement resource block (250r) in the standard transmission mode, implementing a number of signaling portions of signaling portions greater than that used in the standard allocation mode, in each time interval. 15. Signal transmitted by a base station (110) of a radiocommunication network to at least one terminal (100), multiplexing data in resource blocks distributed in time and frequency in time intervals, characterized in that that it comprises at least one signaling portion for the allocation of resources comprising an identification field of the allocation mode implemented in said signaling portion, among standard and temporary allocation modes.